DE3629872A1 - Wind-power installation for generating electrical energy - Google Patents

Abstract

Wind-power installation for generating electrical energy, using a generator that is integrated into a propeller with at least two propeller blades, preferably a horizontal-axis unit. The rotor consists of high-energy permanent magnets with magnetic keepers, and is fastened to the propeller blades as a rotor ring. The stator forms a structural unit with the tower of the wind-power installation. <IMAGE>

Description

The invention relates to a wind turbine according to the Ober understood by claim 1 or 2.

Wind turbines for feeding electrical energy into the electrical supply networks are generally known. With these Plant is generally a wind powered one Propeller over shafts, clutches and gearboxes with the rotor shaft of a generator mechanically connected. This is about it is expensive and heavy designs with one reasonably poor efficiency, where vibration and Vibration problems occur. These facilities can also only difficult with a dynamic sash adjustment will drive and also require complicated brakes.

Generators for wind turbines were integrated into the propeller Proposed for opposing Honef propellers as early as 1938 The disadvantages of these systems are the large rotating the masses and the problem of power transmission for the genera gates over slip rings.

The invention has for its object a wind turbine of the type mentioned in terms of their efficiency and improve their immunity to interference, taking the scheme of the energy flow without adjusting the propeller pitch in the Way should be made possible that the speed to the wind speed and in principle optimal to the size of the propeller.

The object is achieved by the characterizing note male of claims 1 or 2 solved.

Embodiments of the invention are in subclaims 3 to 24 described.

The improvement in aerodynami is particularly advantageous efficiency, a reduction in the weight of the system as well as manufacturing costs, improved vibration and vibration properties of the system and the possibility of using the system easy and safe to brake electrically.

In the drawing are exemplary embodiments according to the invention shown, namely show

Fig. 1 is a horizontal-axis system in side view,

Fig. 2 to Fig. 4 details of ring generators in ver enlarged view, and

Fig. 5 shows the propeller part with a ring generator of a vertical axis system.

In Fig. 1, a frame 2 is rotatably mounted on a tower 1 standing on the ground via a tower slewing ring 3 . The frame 2 has an almost horizontal fixed shaft 4 which interacts with the propeller bearing 5 of the propeller. The rotor 7 of a ring generator, the stator 8 of which is in a mechanically fixed connection to the frame 2 and is thus connected to the frame 2, is fastened to the blades of the propeller, designated 6 , and thus forms a structural unit with the latter. The attached to the stator 8 electrical lines 9 for transferring the generated electrical energy can be performed via a slip ring arrangement, not shown in the drawing, which is arranged at the bearing point between the tower ring gear 3 and tower 1 .

The rotor 7 of the ring generator can either consist of hochenergeti rule permanent magnet with yoke iron, or as a ring made of non-magnetic material, in the highly magnetic permanent magnet without magnetic yoke with a pole coverage factor less than 80% are made. In the first case, the stator 8 has well-known stator windings and can be made in one piece. In the second case, it can - as shown in FIG. 4 - consist of two stator parts, which are designed as internal and external sensors 10 and 11 , which then comprise the rotor 7 and form a structural unit with the tower.

As shown in FIG. 2, the fixed shaft 4 is directly attached to the tower slewing ring 3 cooperating with the tower 1 . The stator 8 is mechanically connected via articulated arms, struts or guide plates 12 to the fixed shaft 4 and thus to the tower slewing ring 3 or the tower 1 . The electrical line 9 is then guided through bores in the articulated arms 12 , the shaft 4 and the tower slewing ring 3 from the stator 8 to a consumer, not shown in the drawing. On the fixed shaft 4 , articulated arms 13 are mounted on both sides to the articulated arms 12 of the stator 8 by means of ball bearings, on the outer ends of which a fastening ring 14 is fastened for receiving the rotor ring 7 . The articulated arms 13 can be designed as wing sections. The fastening ring 14 can be designed as a streamlined nozzle, so that both the stator 8 and the rotor 7 are streamlined.

Fig. 3 shows the section of a system in which, in contrast to the system shown in Fig. 2, the articulated arms 13 for the rotor 7 are in one plane. These articulated arms 13 are practically arranged opposite the propeller blades 6 , so that the stator 8 and the rotor 7 of the ring generator lie outside the plane of rotation of the propeller blades 6 . It is also possible here to form the fastening ring 14 in a streamlined manner.

For the individual components of the embodiment shown in FIG. 4, the reference numerals already used in FIGS. 1 to 3 have been chosen, as far as this is possible. Significant difference to the previously described situations is the stator 8 , which is divided into an inner and an outer stator 10 or 11 . The two stator parts 10 and 11 include the rotor 7 and are directly mechanically connected to the tower 1 of the wind turbine. Here, too, the streamlined clothing of the components forming the ring generator is clearly visible.

The multi-bladed vertical-axis system from FIG. 5 has a stator 8 which is mechanically fixedly connected via articulated arms 15 to a shaft 16 fastened to the tower 1 and serving as the vertical axis of the propeller. The stator is surrounded by a ring element 17 which receives the rotor ring 8 and which is fastened by means of articulated arms, struts or guide plates 18 to a rotary bearing 19 which interacts with the shaft 16 . It is expedient to arrange the articulated arms, struts or guide plates 18 fastened with the ring element 17 parallel and on both sides to the articulated arms 15 fastened to the stator 8 . At the Ringele element 17 are also one end of a wing 20 of the propeller mechanically attached, the other ends of the wing 20 are brought together and serve as a bearing. This storage can be carried out by means of a shaft 21 which is attached to the shaft 16 serving as the vertical axis of rotation. This shaft can be surrounded by a hollow shaft 22 which is attached to the upper end of the blades 20 of the propeller and to the pivot bearing 19 .

In the vertical-axis system, the current draw is even easier than in the horizontal-axis system, since the cable 9 can be guided from the stator 8 directly to a converter not shown in the drawing. It is also advantageous that the torque transmission occurs easily due to lower bending forces, since the wings 20 of the propeller are articulated to the peri-ring element 17 . In three- or multi-blade systems, the wide base of the ring element 17 means that there is no need for an upper guide for the propeller 20 , since the blade combination is freely guided by the rotor.

The following applies in summary to the systems shown in FIGS . 1 to 5:

• 1) The ring generators can be driven by a pulse-controlled inverter and set depending on the rotor speed when the power is output via the pulse-controlled inverter. The permanently excited ring generator can only be driven stably without an additional damper winding by means of the pulse alternating rectifier with voltage intermediate circuit, which simultaneously provides voltage and frequency. The supply to the network takes place via a controlled rectifier. The generator can optimally have a power factor cos ϕ = 1.
• 2) The rotor of the ring generator can be a transverse damping device device and as a converter motor or generator be driven with an impressed intermediate circuit. The Motor and generator operation is without additional com components possible (transverse damping can be copper sheet cover).
• 3) A highly dynamic blade leaf adjustment can be dispensed with, since there is a power-dependent speed setting and in the event of overspeed, emergency braking by short-circuiting the stator is possible, possibly via resistors. In addition, the rotor ring on the propeller blades 6 and 20 offers a favorable friction surface for a claw or shoe brake as a redundant brake due to its large diameter.
• 4) The casing of the ring generator can be used for small diameters knives (generator diameter less than approx. 10% of the Diameter) as so-called Schnitger propeller Nozzle. With larger diameters (generator diameter up to approx. 100% of the propeller diameter) the ring generator can be clad like a jacket turbines or vortex towers as a nozzle part.
• 5) To avoid groove harmonics of the rotor 7 , the permanent magnets can be arranged obliquely to the axial direction of the rotor ring.
• 6) The air gap between stator 8 and rotor 7 of the ring generator can be protected by a labyrinth cladding against the ingress of water. Waterproof plastic cladding or potting is also conceivable.
• 7) The surfaces forming the air gap between the stator 8 and rotor 7 of the ring generator can be designed by grooves or elevations such that there is sufficient cooling circulation of the air. The large surface of the rotor ring 7 with the iron bandage and the articulated arms promote natural cooling.

Further advantages of the plants according to the invention are as follows:

The permanently fed via the self-commutated pulse converter excited synchronous machine requires no pole position transmitter and rain because there is a frequency and subordinate active current control Magnetic wheel or current vibrations prevented. The embossed - Voltage approximated to sinusoidal form results in quasi-sinusoidal current and thus lower losses in the generator.

• - No gearbox and avoidance of its losses, none Oil cooling.
• - High efficiency of the generator (approx. 96 to 97%, cos ϕ = 1).
• - No pathogen losses, no pathogen devices and auxiliary pathogens machine.
• - No active cooling, no single or double cooling systems.
• - Self-start or intentional active start.  
• - No slip rings, only cable connection.
• - Minimal nacelle, only propeller storage.
• - Converter efficiency approx. 2%.
• - Safe electric braking.
• - Easier implementation of a redundant mechanical brake.
• - Improve aerodynamic efficiency.
• - Speed setting through power control.
• - No dynamic wing adjustment required.
• - Parallel operation of several wind power plants on one intermediate circle possible.
• - Less vibration of the wings thanks to the rotor ring.
• - Automatic axial centering by magnetic forces.
• - Longer lifespan and shorter maintenance times because hardly Wear parts.
• - The stator can wind when the propeller is not running alternate feed in forward and reverse direction the pulse inverter can be warmed up against icing.

Claims (24)

1. Wind turbine for generating electrical energy using a generator that is integrated in a propeller with at least two propeller blades, preferably horizontal-axis system, characterized in that the rotor ( 7 ) consists of high-energy permanent magnets with back iron and as a rotor ring is attached to the propeller blades ( 6 ), and that the stator ( 8 ) with the tower ( 1 ) of the wind turbine forms a structural unit. 2. Wind turbine for generating electrical energy using a generator which is integrated in a propeller with at least two propeller blades, preferably horizontal-axis system, characterized in that the rotor ( 7 ) consists of a ring made of non-magnetic material, in the high-energy Permanent magnets without magnetic yoke with a pole coverage factor of less than 80% are inserted, that the ring ( 7 ) on the propeller blades ( 6 ) is mechanically fastened, and that the stator ( 8 ) consists of two, as an inner and an outer stator ( 10 , 11 ) formed stator parts which comprise the rotor ( 7 ) and form a structural unit with the tower ( 1 ) of the wind power plant. 3. Wind turbine according to claim 1 or 2, characterized in that the rotor ring ( 7 ) together with the propeller blades ( 6 ) and the stator ( 8 ) about a vertical axis by means of a tower slewing ring ( 3 ) rotatable on the tower ( 1 ) Wind turbine is attached. 4. Wind power plant according to claim 3, characterized by a slip ring arrangement, which is provided at the bearing point between the turret ring ( 3 ) and tower ( 1 ) and the electrical lines coming from the stator ( 8 ) with the lines leading to the consumer ( 9 ) electrically leading connects. 5. Wind turbine according to claim 1, 2, 3 or 4, characterized in that the stator ( 8 ) is streamlined. 8. Wind power plant according to claim 1, 2 or 3, characterized in that the rotor ring ( 7 ) ausgebil Dete articulated arms as wing sections ( 12 ). 7. Wind turbine according to claim 1, 2, 3, 5 or 8, characterized in that the rotor ring ( 7 ) is streamlined clad ver. 8. Wind power plant according to claim 1, 2, 3, 4 or 5, characterized in that the stator ( 8 ) via articulated arms, struts or guide plates ( 12 ) with the tower ( 1 ) or tower slewing ring ( 3 ) is mechanically connected. 9. Wind power plant according to claim 1 or 2, wherein a two or more-bladed vertical-axis system, preferably of the Darrieus type, is used, characterized in that the stator ( 8 ) via articulated arms ( 15 ) with the on the tower ( 1 ) fasten th and as the vertical axis of rotation of the propeller shaft ( 16 ) is in a mechanically fixed connection that the stator is surrounded by a ring element ( 17 ) which receives the rotor ring and on the periphery of which one end of the wing ( 20 ) of the propeller is mechanically fastened , and that the ring element ( 17 ) via articulated arms, struts or housing plates ( 18 ) is attached to a rotary bearing ( 19 ) which cooperates with the shaft serving as a vertical axis of rotation ( 16 ). 10. Wind power plant according to claim 9, characterized in that the articulated arms, struts or housing plates fastened in the ring element ( 17 ) are arranged parallel and on both sides to the articulated arms ( 15 ) fastened to the stator ( 8 ). 11. Wind turbine according to claim 9, characterized in that the upper ends of the wings ( 20 ) of the propeller miteinan mechanically connected and as a bearing ( 23 ) for a shaft shaft ( 21 ) are formed on the shaft serving as a vertical axis of rotation ( 16 ) is mechanically attached. 12. Wind power plant according to claim 9, characterized in that the upper ends of the blades ( 20 ) of the propeller with one end of a hollow shaft ( 22 ) are in mechanically fixed connection, which is attached at its other end to the rotary bearing ( 19 ), and that the hollow shaft is penetrated by the shaft shaft ( 21 ). 13. Wind turbine according to claim 1, 2, 3 or 9, characterized in that the stator ( 8 ) and rotor ring ( 7 ) gebil Dete ring generator started by a pulse inverter and rotor output is made dependent on the power output via the pulse inverter. 14. Wind power plant according to claim 13, characterized by braking the ring generator by short-circuiting the stator ( 8 ). 15. Wind turbine according to claim 14, characterized by the use of resistors. 16. Wind turbine according to claim 5 or 6, characterized in that the cladding of the stator ( 8 ) and rotor ring ( 7 ) formed ring generator with small diameters (for example, generator diameter smaller than about 10% of the propeller diameter) as a so-called Schnitger Propeller nozzle is running. 17. Wind power plant according to claim 5 or 6, characterized in that the cladding of the stator ( 8 ) and rotor ring ( 7 ) formed ring generator with larger diameters (for example generator diameters up to 100% of the propeller diameter) as in jacket turbines or vortex towers as a nozzle part is led. 18. Wind turbine according to claim 1, 2 or 9, characterized in that a part of the ring which carries the permanent magnets ( 7 ) is used as a brake ring for a shoe or claw brake additional Lich. 19. Wind turbine according to claim 1, 2 or 9, characterized in that the permanent magnets are arranged obliquely to the axial direction of the rotor ring to avoid groove harmonics of the rotor ( 7 ). 20. Wind turbine according to claim 1, 2, 9, 13, 14 or 17, characterized in that the air gap between the stator ( 8 ) and rotor ( 7 ) of the ring generator is protected by a labyrinth clothing against the ingress of water. 21. Wind turbine according to claim 1, 2, 9, 13, 14, 16, 17 or 20, characterized in that the air gap between the stator ( 8 ) and rotor ( 7 ) of the ring generator forming upper surfaces designed by grooves or surveys are that there is sufficient cooling circulation of the air for the generator. 22. Wind power plant according to claim 13, characterized in that the winding of the stator ( 8 ) is heated against icing when the propeller is at a standstill by alternately feeding in the forward and reverse directions by the pulse inverter. 23. Wind power plant according to one of claims 1 to 9, 13, 14 or 16 to 22, characterized in that the rotor ( 7 ) of the ring generator has a transverse damping device, and that the ring generator is operated as a converter motor or generator with an impressed intermediate circuit. 24. Wind turbine according to claim 23, characterized by the use of a copper sheet cover of the rotor to its Transverse damping.